A substrate support is provided, is configured to support a substrate in a plasma processing chamber, and includes first, second and third insulative layers, conduits and leads. The first insulative layer includes heater zones arranged in rows and columns. The second insulative layer includes conductive vias. First ends of the conductive vias are connected respectively to the heater zones. Second ends of the conductive vias are connected respectively to power supply lines. The third insulative layer includes power return lines. The conduits extend through the second insulative layer and into the third insulative layer. The leads extend through the conduits and connect to the heater zones. The heater zones are connected to the power return lines by the leads and are configured to heat corresponding portions of the substrate to provide a predetermined temperature profile across the substrate during processing of the substrate in the plasma processing chamber.

Apparatus and methods for processes of depositing a film on a substrate in an electronic device fabrication process are provided herein, and more particularly, apparatus and methods for improving deposited film uniformity within high aspect ratio features. In some embodiments, a metal layer deposition process is performed to deposit a metal layer in a feature definition formed in a substrate. A mask layer deposition process is performed to deposit a carbon layer on the metal layer. Following the mask layer deposition process, a resputtering process is performed by applying a radio frequency (RF) signal to the substrate in a presence of an inert gas. Following performing the resputtering process, an etching process is performed to remove the carbon.

Thin tin oxide films are used as spacers in semiconductor device manufacturing. In one implementation, formation of spacers involves deposition of a tin oxide layer on a semiconductor substrate having multiple protruding features. The deposition is performed in a deposition apparatus having a controller with program instructions configured to cause sequential contacting of the semiconductor substrate with a tin-containing precursor and an oxygen-containing precursor such as to coat the semiconductor substrate having the protruding features with a tin oxide layer. Next, tin oxide film is removed from horizontal surfaces, without being completely removed from the sidewalls of the protruding features. Next, the material of protruding features is etched away, leaving tin oxide spacers on the semiconductor substrate.

A method of processing a target object is provided. The target object includes a first protrusion portion, a second protrusion portion, an etching target layer and a groove portion. The groove portion is provided on a main surface of the target object, provided on the etching target layer and defined by the first and the second protrusion portions. An inner surface of the groove portion is included in the main surface. In the method, a first sequence is repeatedly performed N times (N is an integer equal to or larger than 2). The first sequence includes (a) forming a protection film conformally on the main surface in a processing vessel of a plasma processing apparatus in which the target object is accommodated; and (b) etching a bottom portion of the groove portion with plasma of a gas generated within the processing vessel after the process a is performed.

A device and method of spreading plasma which allows for plasma etching over a larger range of process chamber pressures. A plasma source, such as a linear inductive plasma source, may be choked to alter back pressure within the plasma source. The plasma may then be spread around a deflecting disc which spreads the plasma under a dome which then allows for very even plasma etch rates across the surface of a substrate. The apparatus may include a linear inductive plasma source above a plasma spreading portion which spreads plasma across a horizontally configured wafer or other substrate. The substrate support may include heating elements adapted to enhance the etching.

The present disclosure provides an etching method that includes a resist pattern-forming step of forming a resist layer on a target object, the resist layer being formed of a resin, the resist layer having a resist pattern; an etching step of etching the target object via the resist layer having the resist pattern; and a resist protective film-forming step of forming a resist protective film on the resist layer. The etching step is repetitively carried out multiple times. A processing gas, used in the resist protective film-forming step, includes a gas capable of forming Si.sub.xO.sub.y?.sub.z; wherein a is any one of F, Cl, H, and C.sub.kH.sub.l; and each of x, y, z, k, is a selected non-zero value. After the etching steps are repetitively carried out multiple times, the resist protective film-forming step is performed.

A gas supply ring for use in a substrate processing apparatus includes an inner face, an outer face, a first face between the inner face and the outer face, and a second face between the inner face and the outer face and opposite to the first face. The outer face has at least one gas inlet and the first face has an outer groove in communication with the at least one gas inlet. The second face has first and second middle grooves in communication with the outer groove. The first face further has first to fourth inner grooves disposed medial to the outer groove. The inner face has a plurality of gas outlets and each of the gas outlets is in communication with any one of the first to fourth inner grooves.

Processes for removing a photoresist from a substrate after, for instance, ion implantation are provided. In one example implementation, a process can include placing a substrate having a bulk photoresist and a crust formed on the bulk photoresist in a processing chamber. The process can include initiating a first strip process in the processing chamber. The process can include accessing an optical emission signal associated with a plasma during the first strip process. The process can include identifying an endpoint for the first strip process based at least in part on the optical emission signal. The process can include terminating the first strip process based at least in part on the endpoint. The process can include initiating a second strip process to remove the photoresist from the substrate.

Apparatus for processing substrates can include a gas distribution plate that includes an upper plate and a lower plate and a solid disk between the upper plate and the lower plate. Each of the upper plate and the lower plate has a central region and an outer region surrounding the central region, the central region being solid and the outer region having a plurality of through holes. The upper plate and the lower plate are coaxially aligned along a central axis extending through a center of the central region of the upper plate and a center of the central region of the lower plate. The solid disk is coaxially aligned with the upper plate and the lower plate. The solid disk is configured to block transmission of ultraviolet radiation through the solid disk.

Plasma is generated using elemental hydrogen, a weak oxidizing agent, and a fluorine containing gas. An inert gas is introduced to the plasma downstream of the plasma source and upstream of a showerhead that directs gas mixture into the reaction chamber where the mixture reacts with the high-dose implant resist. The process removes both the crust and bulk resist layers at a high strip rate, and leaves the work piece surface substantially residue free with low silicon loss.